Oscillating and locking apparatus and method for vibrating tray weighing scale

ABSTRACT

Oscillating and alternatively locking apparatus and method of determining the mass of an article by the shift of the period of oscillation of a flexibly mounted platform. An article whose mass is to be determined is placed upon the platform. The platform is caused to oscillate and the period of harmonic motion is calibrated. This period is compared against the period of harmonic motion when there is no article upon the platform, and the difference, or shift, in frequency, allows a determination of the mass of the article. A reversible motor is used to provide drive to a conveyor for transporting mail pieces onto the tray and for causing oscillation of the tray for purposes of weighing.

BACKGROUND OF THE INVENTION

As technology progresses, processes tend to proceed at a faster pace.Most processes require the coordination of a number of components, andthe process can only proceed as fast as the slowest component allowsunless multiple like components are used. There are certain processes inwhich the weight of an article is required, but to date no scale hasbeen available that provides accurate, fast weighing. By accurate ismeant the ability to weigh an object having a weight of up to 32 ounceswithin 1/32 of an ounce. By fast is meant the ability to weigh a streamof conveyed articles within less than one second per article. A processwhere there is a need for fast weighing is in the processing of mail.High speed systems have been developed whereby the appropriate number ofinserts, which number may vary from envelope to envelope, are placedwithin an envelope. The envelope is sealed and postage is printed on theenvelope. Before the postage can be printed, however, it is necessarythat the weight of the mail piece be determined. Heretofore, weighingdevices for such mail processing systems have been developed, but thesegenerally have been rather slow. Actually, many prior weighing devicescombined a standard scale with a mechanism that would stop the mail toallow weighing to take place. In order to accommodate the output of aninserter, multiple scales would be used with alternate mail piecesdiverted to such scales.

Much effort has been expended in trying to develop a weighing scale thatmeets the heretofore enumerated goals. One weighing scale that has beenfound highly successful in this endeavor is described in co-pendingpatent application entitled APPARATUS AND METHOD OF DETERMINING THE MASSOF AN ARTICLE BY MEASURING THE SHIFT IN THE PERIOD OF HARMONIC MOTION,filed July 13, 1987 and having Ser. No. 073,790. The scale described inthe co-pending application, as well as others of its type require afast, efficient method of feeding locking the various components whenarticles are being conveyed onto the tray of the scale and for releasingand vibrating the tray during the weighing operation.

SUMMARY OF THE INVENTION

A unique locking and oscillating device has been conceived for a scaleutilizing the principles of harmonic vibration for the purposes ofdetermining the weight of an article. A flexibly mounted tray has afinger depending therefrom that contacts an angled surface. In oneoccurrence the tray is caused to oscillate. From the frequency of theoscillation the mass of an article on the tray can be determined. Afterthe mass is determined the finger is engaged by a different part of theangled surface to lock the tray.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a scale that incorporates the instantinvention;

FIG. 2 is an exploded perspective view showing selected parts of thescale shown in FIG. 1;

FIG. 3 is a cross-sectional longitudinal view of the scale shown in FIG.1;

FIG. 4 is a plan view taken along the lines 4--4 of FIG. 3;

FIG. 5 is an end view taken along the lines 5--5 in FIG. 4;

FIG. 6 is a cross-sectional view of a flexure member that is part of thescale shown in FIG. 1;

FIG. 7 is a side elevational view taken along the lines 7--7 of FIG. 4;

FIG. 8 is a side elevational view taken along the lines 8--8 of FIG. 4;

FIG. 9 is a side elevational view taken along the lines 9--9 of FIG. 4;

FIG. 10 is a side elevational view taken along the lines 10--10 of FIG.4;

FIG. 11 is a block diagram of the circuitry employed within the scaleshown in FIG. 1;

FIG. 12 is a block diagram of the components of the electroniccontroller shown in FIG. 11;

FIGS. 13a-13b are graphs that show a single pulse applied to theweighing device, a plot of the output generated by a transducer as aresult of the oscillation, and a square wave form of the output,respectively; and

FIG. 14 is a flow chart describing the steps involved in measuring themass of an article.

DETAILED DESCRIPTION OF THE INVENTION

With reference to FIG. 1, a weighing scale that incorporates the instantinvention is shown generally at 12 and includes a housing 13 that isopen at the top 14. The components contained within the housing 13 areshown in FIGS. 2-10, and, with reference to FIG. 2, include a frame 18that is attached to the floor of the housing and supports four uprights16. To each upright 16 a leaf spring 20 is attached by means of a cap 22that is bolted to the upright with a portion of the leaf springtherebetween. It will be noticed that the leaf springs are formed at anangle and have a lower portion that is adjacent to one of two laterallyextending plates 24. The angle of the leaf spring is preferably between5' and 15' relative to the vertical. The springs 20 are bolted to theplates 24 by a cap 26, the lower portion of the springs being locatedbetween the caps 26 and the plates 24. In this way the two plates 24 aresupported by the frame 18 through the springs 20 to be isolatedtherefrom.

Secured to each of the plates 24 are a pair of flexible members 30having a general parallelogram configuration, the details of whosestructure is shown in FIG. 6. Each flexible member 30 has a pair ofopposed sides 32. A transducer 33 is secured to at least one of thesides 32 of one of the flexible members 30. This transducer may be adevice such as a piezoelectric device such that a voltage is generatedin accordance with the bending of the transducer. The flexible members30 have a pair of openings 34 at the bottom thereof that receive bolts36 that extend through the plates 24 to thereby secure the flexiblemembers to the plates. The flexible members 30 also have an opening 38at the top thereof that are in registration with openings 42 within atray 40. The tray 40 is attached to the flexible members 30 as by bolts41 that are received within the openings 38 of the flexible members. Thetray 40 also has a longitudinally extending opening 44 therein. The tray40 is in the form of an inverted dish with a honeycomb configurationshown generally at 46 so as to provide light weight to the tray 40.

Four uprights 48 are attached to the two plates 24 and mounted thereonis a base 50 having generally "T" shaped members 52 with dependentportions 54 attached thereto. The purpose of the T shaped members 52 anddependent portions is to increase the weight of the base 50. Withreference to FIG. 3, two pairs of opposed brackets 60 are supported bythe base 50 and each pair of brackets supports a pin 52 therebetween. Anidler pulley 64 is rotatably mounted on each of the pins 62. Withreference to FIGS. 3 and 5, a pair of opposed brackets 66 are supportedby the frame 18 and each bracket has a bearing 68 therein that receivesa shaft 70 that is thus supported by the opposed brackets. A pulley 72is disposed upon the shaft 70, there being a one way bearing 74 betweenthe pulley 72 and shaft 70 thereby allowing the pulley to be freewheeling relative to the shaft when the pulley is rotated in onedirection, i.e. no drive will be transmitted therebetween, but the shaftwill be driven by the pulley when the pulley is pulley driven in theopposite direction. The pulley 72 has a sleeve portion 76 about whichanother pulley 78 is mounted with a one way bearing 80 therebetween. Theone way bearing 80 will be opposite in terms of functional direction tothat of the one way bearing 74 so that when the pulley rotates in theclockwise direction, as seen in FIG. 3, the one way bearing 80 willprovide drive between the pulley 72 and pulley 78 but when the pulley 72is driven in the counter clockwise direction, pulley 78 is free wheelingand no drive is transmitted therebetween.

A bracket 82 mounts a reversible motor 84, there being a pulley 86secured to the output shaft 88 of the motor. A belt 90 is trained aboutthe pulleys 72,86 to provide drive to the pulley 72.

A stepped bracket 94 is mounted to the tray 40 and supports a light 92.A photodetector 95 is located immediately below the tray 40 there beingan opening within the tray for light to pass through. The detector is inalignment with the light 92 so as to sense the presence of an objecttherebetween. The bracket 94 supports a plurality of shafts 96 to whichpaired arms 98 are attached, there being pins 100 extending between andjoining the paired arms, each pin supporting a idler roller 102. Atension spring 104 is supported by each of the shafts 96, the tensionspring having a first tang 106 that abuts the bracket 94 and a secondtang 108 that is in engagement with the upper part of one of the pairedarms 98. With this construction, the arms 98 are biased towards the tray40. A pair of arcuate skis 110 are located on each of the paired arms98. A mail piece 112 in the form of an envelope is shown in FIG. 3 in aposition in which its weight would be determined by the weighing scale12.

With reference to FIGS. 4 and 8, two pairs of stanchions 114 are locatedopposite one another in a paired relationship and connected by a shaft116 that is supported fixedly by each pair of stations 114. Rotatablysupported by each shaft 116 are a pair of generally L-shaped arms 118that are joined together by a connector 120. Secured to each connector120 is a follower 122. The upper portions of the arms 124 are rotatablysupported by pins 126 that are received within a pair of brackets 128.The brackets 128 are connected to one another by shafts 130 thatrotatably receive intermediate rollers 132 and end rollers 134, thelatter being slightly larger. Each of the brackets 128 has an elongatedslot 136 therein that receive the shaft 116 thereby allowing movement ofthe brackets relative to the shaft. A pair of cams 138,140 are mountedon the shaft 70, one of the cams 140 being in engagement with the camfollower 122. A stanchion 141 having a longitudinal extending opening142 therein slidably receives a rod 144 within such opening. The rod 144is in engagement with the cam 138 at one end, and a follower 122 of anarm 118 at its other end. A tension spring 146 is secured to opposedpairs of arms 118 for the purpose of urging the followers 122 againstthe cam 140 and rod 144, respectively.

Referring now to FIGS. 4 and 7, the frame 18 has mounted thereon anabutment 152. The shaft 70 fixedly supports a cam 154 that has a largediameter portion 156 and a small diameter portion 158. Disposed aboutthe shaft 70 is a spring 160 having one tang 162 that is received withinan opening 164 of the cam, and another tang 166 that is received withinthe opening 168 of the stanchion 66. The spring rotates the cam 154 andthe shaft 70 in the clockwise direction as seen in FIG. 7 to therebyurge the cam portion 156 against the abutment 152.

With reference to FIGS. 5 and 9, the scale 12 has a mechanism 169responsive to the shaft 70 for locking and initiating oscillation thatincludes a cam 170 that has an opening 171 therein with a first camedsurface 172 and a second camed surface 174, the cam 170 being mounted onthe shaft 70 for rotation therewith. A support 176 is located on thebase 50 and a shaft 178 is attached to this support. A generally Vshaped link 180 is mounted about the shaft 178 with a friction bearing179 located therebetween. The function of the friction bearing is tocreate a resistance to movement on the part of the link 180 so thatforce is required to rotate the link about the shaft. The generally Vshaped link 180 has a first arm 182 and a second arm 184, the latterhaving a cam follower 186 at the end thereof that is received within theopening 171. The first arm 182, has a projecting portion 188 that has anangular bearing surface 190 with a shoulder 192 at the end thereof. Afinger 194 depends from the tray 40 and has a rectangular abutmentmember 196 that is engageable with the projection 188 to lock the tray40 to the base 50. The rest position of the tray 40 as a result of theflexible members 30 is such that the abutment portion would be locatedat a position midway of the angular bearing surface 190.

Referring now to FIGS. 5 and 10, a locking mechanism 198 is provided forlocking the tray 10 during the periods when objects to be weighed aretransported onto the tray and releasing the tray 40 during oscillation.A lambda (upper case) shaped stanchion 200 is supported by the frame 18and has a pin 202 extending therefrom. A generally Z shaped link 204 isrotatably supported by the pin 202 and has a first leg 206, and a secondleg 207, the latter having an opening 208 therein. A post 210 issupported by the frame 18 and a tension spring 212 extends from theopening 208 to the post 210 to urge the arm link 204 in a counterclockwise direction. A first leaf spring 214, preferably made ofstainless steel is supported by and extends from the stanchion 200towards and is in spaced relationship with the second leg 206. A finger216 depends from the base 50 and supports a second leaf spring 218 thatextend intermediate the first leaf spring 214 and the stanchion 200 soas to lock the base 50 as a result of the force applied by the leg 206resulting from the biasing effect of the spring 212. Mounted on theshaft 70 is a cam 220 for rotation therewith. This cam 220 engages thelink 204 as the shaft 70 rotates to overcome the effect of the spring212 and urge the link in a clockwise direction and disengage the leg 206from the leaf spring 214, thereby unlocking the base 50 from the frame18.

Referring now to FIG. 11, a controller 221, the details of which areshown in FIG. 12, is in communication with a computer 222 that has aswitch 224 for connecting the scale with line power and a display 226where the weight of an object that is determined by the scale will beshown. The electronic controller 221 is in electrical communication withthe photosensor 95, the drive motor 84 and the piezoelectric 33.

The components of the electronic controller 130 are shown in FIG. 12 andinclude a band pass filter 228 that receives the output from thepiezoelectric transducer 33 and is connected to a zero crossing detector230. The band pass filter 228 eliminates high frequency electrical noiseand low frequency mechanical noise from the signal received from thepiezoelectric transducer 33. In electrical connection with the band passfilter 228 is the zero crossing detector 230 which converts the signalreceived from the band pass filter to a square wave. The zero crossingdetector 230 is in electrical connection with an edge detector 232 thatdetects the edge of each square wave produced by the zero crossingdetector. The edge detector 232 is in electrical connection with aflip-flop 234 that receives an input from a AND gate 236. The AND gate236 is in connection with the computer 222 and a counter 238 that hasinput from a clock 240 and the edge detector 232. A one shot vibrator241 is in connection with a flip-flop 242 and with the photosensor 95.The flip-flop 242 is in communication with the computer 222. Thus, as amail piece 112 is sensed by the photosensor 33, the one shot vibrator241 will send a pulse to the flip-flop 242 which in turn willcommunicate to the computer 222 the presence of a mail piece.Alternatively, after a mail piece 112 is conveyed away from the tray 40to no longer be sensed by the photosensor 33, the one shot 241 willagain pulse the flip-flop 242 to signal the computer 222.

In operation, power is supplied to the scale 12 by enabling the switch224 located on the computer 222. Although the switch is shown on thecomputer 222, it is apparent that this is not critical in any convenientmeans may be used for providing power to the scale 12. With powersupplied to the system, the motor 84 will be caused to drive in aclockwise direction thereby rotating the pulley 72 through the belt 90.With rotation of the pulley 72, the pulley 78 will be rotated due to thepresence of the one way bearing 80. The pulley 78 is driven in aclockwise direction as seen in FIG. 3 thereby driving the belt 148. Withthe belt 148 being driven, the pulley 64 and the drive rollers 134 willalso be driven. The smaller rollers 132 act as support for the belt 148as it moves within the opening 44 of the tray 40.

It will be noted that as the belt 148 is being driven, the shaft 70 isstatic. This results from the presence of the one way bearing 74 whichallows the shaft 70 to remain free wheeling within the rotating pulley72 when the latter is driven in the clockwise direction. With the shaft70 being static, the tray 40 is locked to the base 50 because of thelocking oscillating mechanism 169 and the base 50 is locked to the frame18 because of the locking mechanism 198. When a mail piece 112 is to beweighed, it is placed upon the tray 40 at the location of the belt 44and conveyed between the belt and the idler rollers 102. Because of thebiasing action of the springs 104 upon the arms 98, the rollers 102 willengage a mail piece 112 and urge it against the belt 148 until such timeas the mail piece envelope 112 comes between the light 92 andphotosensor 95. Upon this occurring, the photosensor 95 will send asignal to the computer 222 indicating the presence of the envelope 112.Upon this occurring, the computer 222 will cause the electroniccontroller to reverse the angular rotation of the drive motor 84 fromclockwise to counter clockwise. This counter rotation will be for only a180° rotation of the motor output shaft 86.

With the motor 84 rotating in the reverse direction 180°, the drive tothe belt 148 will be terminated and the shaft 70 will be rotated 180°.This results from the pulley 72 being rotated in the opposite direction180° thereby allowing the pulley 78 to be free wheeling due to thepresence of the one way bearing 80. Meanwhile, the one way bearing 74will transmit drive from the pulley 72 to the shaft 70. With suchrotation of the shaft, the spring 160 will be overcome and the cams138,140, the cam 154 and the cam 170 will also be rotated half arevolution.

With reference to FIG. 8, FIG. 8A shows the posture of the brackets 128and the rollers 132,134 that are supported thereby when the motor 84 iscontinuously driving in a clockwise direction. This is the posture inwhich a mail piece 112 will be transported across the tray 40 by thebelt 148. As the motor 88 rotates in an opposite counter clockwisedirection half a revolution, the cams 138 and 140 are rotated by theshaft 70 so as to assume the position shown in FIG. 8B. In this posturethe cams 138,140 are rotated so that their surfaces are driven away fromengagement with the rod 144. With this occurring, the tension spring 146will pull upon the opposed paired arms 118 towards one another tothereby urge one of the cam followers 122 against the cam surface 140and the other cam follower 122 against the rod 144. With this occurring,the rod 144 will move to maintain engagement with the cam 138, to theleft as seen in FIG. 8, and the arms 118 will be rotated in unison withthe shaft 116 with the opening 136 thereby causing the bracket 128 tomove downwardly. The presence of the elongated slot 136 in the armsbracket 128 provides the space required for such movement. As thebracket 128 is pulled down by the action of the arms 114, it carriestherewith the belt 148 and the accompanying rollers 132,134 out of theopening 44 of the tray. With reference to FIGS. 3 and 5, upon thisoccurring, the springs 90 will urge the arms 98 downwardly therebyurging the rollers 102 against the mail piece 112 and the skis 110against the mail piece at the location of the tray 40. When in the drivecondition, the belt 148 was located within the slot 44, the rollers 102engaged the mail piece so as to cooperate with the drive thereof and theskis 110 were at a location slightly above the envelope. With the belt148 removed from the opening 44, the rollers 102 will engage the mailpiece at the location of the opening, the skis 110 will hold the mailpiece against the tray 40. In this way, the mail piece 112 is heldfirmly against the tray 40 during oscillation of the tray as will bedescribed hereinafter so that an accurate weight can be made. Obviously,if the envelope experiences any movement during oscillation, aninaccurate weighing would not be obtained.

With reference to FIG. 10, upon rotation of the shaft 70, the cam 220will be rotated in the counter clockwise direction and engage the link204. This will cause the link 204 to be rotated about the pin 202 in aclockwise direction thereby disengaging the first leg 206 from the leafsprings 214,218 and unlocking the base 50 from the frame 18.

Referring now to FIGS. 5 and 9, when the tray 40 is in the postureassumed when the motor is rotating in a clockwise direction, the cam 170is in the position as shown in FIG. 9A. In this position, the tray 40 islocked to the base 50 by the presence of the arm 182 engaging the finger194. More specifically, the shoulder 192 will receive the abutmentmember 196 and hold it firmly. It will be recalled that the spring 160urges the opening 171 against the cam follower 186 to rotate the link180 in a clockwise direction. As the shaft 70 is rotated a halfrevolution by the motor 84, the cam 170 begins to rotate in the counterclockwise direction as shown in FIG. 9A and the cam follower 186 willfollow the first surface 172 until such time as it comes to the end ofthe opening whereupon the arm 182 will be rotated about the shaft 178 inthe counter clockwise direction, thereby releasing the finger 194. Morespecifically, the rectangular abutment member 196 will lose engagementwith the shoulder 190 thereby causing the tray 140 to oscillate as aresult of the tray 40 seeking its rest position. After a weighing hastaken place, and the shaft 70 is rotated to its original position, as aresult of the motor rotating the pulley 76 clockwise to release theshaft and the spring 160 rotating the shaft 70 half a revolutionclockwise. The cam follower 186 will now follow the contoured surface174 to thereby urge the arm 182 into a clockwise direction. With thisoccurring, the rectangular portion 196 will slide along the angleportion 188 thereby urging the tray 40 to the right as shown in FIG. 9and away from its rest position until such time as the abutment member196 once more is cradled into the shoulder 190. In this position of thetray 40, the flexure members 32 are flexed slightly to apply a force onthe tray to the left as seen in FIG. 9 so that the tray will oscillateupon being released by the locking and oscillating member 169 as justdescribed.

With the tray 40 oscillation created as described heretofore, theflexure members 30 will be flexed and a voltage will be generated by thepiezoelectric transducer 33. This voltage plotted relative to time willproduce a sinusoidal curve as shown in FIG. 13a. It will be noted thatthe flexure members 32 have a parallelogram configuration with the arms32 parallel to one another. This is advantageous over having a singleflexure member for the reason that when such a flexure member bends, itexperiences a displacement that is non-linear relative to the stress inthe transducer. This results with a frequency that is amplitudedependent. This is a disadvantage because using an amplitude dependentfrequency to determine weight cannot be controlled very well. With theflexure member 30 having parallel arms 32, as shown in FIG. 6, the topof the flexure member, as well as the tray 40, moves generally parallelso that it does not exert a torque on the tray. The tray 40 does move toa somewhat lower position when the flexure members 30 bend, but this isnot a particular problem. With a single flexure member, there is aslight bend of the tray. This slight bend contributes to spring constantof the scale and since the tray is not a good elastic material, there isa deterioration of the ability to determine the weight of an object orthe tray.

Upon oscillation of the tray, the transducer 33 will send the signal asindicated in FIG. 13 and the weight will be determined.

After the shaft 70 has been rotated a half revolution by the motor asdescribed, the tray 40 is unlocked for the base 50 and the base isunlocked for the frame 18. The plates 24 are suspendingly supported bythe leaf springs 20 to the frame to thereby isolate the base fromvibrations experience by the base. Angular leaf springs have been foundto be advantageous because they inhibit lateral movement of the base 50while still providing the required isolation.

The manner of determining weight will now be described. With the tray 40having no mail piece 112 thereon, the motor 84 is actuated to drive thebelt 90 half a revolution in the reverse direction. This causes thefirst arm 182 to disengage from the finger 194 to occasion oscillationof the tray 40 as described previously with the reference to FIG. 9. Thetray 40 will oscillate in the same horizontal direction as the mailpieces 112 are to be conveyed, i.e., in the plane of the tray, left andright as seen in FIG. 3. This is preferable otherwise the mail pieces112 may tend to bounce. As the flexible member 30 with the transducer 33thereon is flexed and continues to oscillate, the transducer will outputan alternating voltage that will have a frequency depending upon themass of the tray 40 and anything secured thereto. It will be noted thatthe tray 40 has the idler rollers 102 and the mechanisms for supportingthe idler rollers attached thereto and is part of the mass thatinfluences the frequency. As the tray 40 oscillates, its oscillation ismeasured by the transducer 33 as an output voltage as shown in FIG. 13.When the tray 40 is first oscillated, the sinusoidal curve is notsymmetric and at least one cycle is required before a uniform curve isobtained. Consequently, a delay is required before measurements can betaken, this delay being programmed into the computer 222 and isapproximately 0.024 secs. After the delay, the frequency, or period, ofzero crossings is determined by the electronic controller 221. After thefrequency of zero crossings is determined, an article such as anenvelope or mail piece 112 is placed upon the tray 40. This isaccomplished by first supplying power to the motor 84 and othercomponents by closing the switch 222. Thereafter a mail piece 112 isplaced upon the tray 40 by any standard mail piece conveying means untilit is received within the nip of the belt 112, and the first idlerroller 102. The mail piece 112 will then be driven onto the tray 40 byaction of the belt 112 and rollers 102 and will be sensed by thephotosensor 95. Upon the mail piece 112 being sensed, the drive motor 84will be rotated half a revolution in the opposite direction and thebrackets 128 lowered, as described previously with reference to FIG. 8,thereby lowering the belt 148 below the plane of the tray 40. As thebrackets 128 are pulled down from the tray 40, the belt 148 becomesdisengaged from the mail piece 112 that is located upon the tray 40. Inthis state the tray 40 will have a new mass, which now includes the massof the mail piece 112. It will be appreciated that the mail piece 112will be held securely upon the tray 40 because the rollers 102 will belowered slightly into the opening 44 and the skis 110 will press themail piece 112 against the tray as a result of the biasing action of thesprings 104 so the mail piece and tray 40 will move as a unit.

With the mail piece 112 on the tray 40 in its weighing position, i.e.,under the rollers 102, the locking and oscillating mechanism 169 willonce more be enabled causing the tray 40 to oscillate, as describedpreviously, in the same horizontal plane and direction as the mail piece112 is transported. This oscillation will be sensed by the transducer 92and the period of oscillation will be measured as described previously.From this, one will be able to determine the mass of the mail piece 112located upon the tray 40 in accordance with the formula:

    M.sub.E =C.sub.1 (T.sup.2 -T.sub.0.sup.2)+C.sub.2 (T.sup.2 -T.sub.0.sup.2).sup.2,                                    (1)

where M_(E) is the mail piece 112 mass, T₀ is the period of oscillationwith no mail piece and T is the period with the mail piece present uponthe tray 40. T₀, C₁ and C₂ are constants which depend on the mass of thebase 50, and the mass of the tray 40 as well as on the spring constantsof the isolation springs 20 and the flexible supports 30. Theseconstants are determined empirically in a calibration procedure in whichthe periods are determined for at least two different masses as well asfor the empty scale. In the limit that the base 50 is substantiallyheavier than the mass of the tray 40 plus the mass of the mail pieces112, the constant C₁ is given by the formula:

    C.sub.1 ≃K/(4π.sup.2),                    (2)

where K is the spring constant of the flexible supports 30. In the samelimit T₀ is given by the formula:

    T.sub.0.sup.2 @(4π.sup.2) M.sub.p /K,                   (3)

where M_(p) is the tray 40 mass.

When a spring is attached to two isolated masses m and M, its period ofoscillation is

ti T² =4π² μ/K. (4)

where μ is the reduced mass:

    μ=mM/(m+M).                                             (5)

In the limit where M is much larger than m, the reduced mass is lessthan and close to the value of m. Equation (4) can be solved for m interms of T. In the scale 12, the base 50 mass M is much larger than m,the combined tray 40 and mail piece 112 mass; however, due to theaccuracy required, the difference between μ and m must be taken intoaccount. This is done by combining equations 4 and 5.

There are other corrections to the period due to the fact that thesystem is damped slightly and due to the fact that the base 50 isattached to the frame 18 through the isolation springs 20. The system isfurther complicated by the fact that the attempt to determine the periodis done through measurements of the first few periods of oscillation.During this time, some initial transients due to the initial pulse areoccurring. As a result, it can be said that the mass is a non-linearfunction of the period squared with the leading non-linearity given byequations 4 and 5. It has been observed empirically that thenon-linearity can be approximated by a parabola represented by equation1.

The mass is determined by the circuitry shown in FIGS. 11 and 12. Thecomputer 222, which may be any of a number of standard commerciallyavailable computers such as a Compaq Model 286 PC, is in communicationwith the electronic controller 221. The transducer 33 will output avoltage that is filtered by the band pass filter 228 and applied to thezero crossing detector 230 which is basically an operational amplifierthat saturates at five volts to output a square wave as shown in FIG.13b. The duration of the square wave yields the time between zerocrossings which is determined by the edge detector 232. The edgedetector 232 outputs a pulse when each edge of the square waves isdetected, which of course, represents zero crossings. These outputs aresent to the counter 238 that counts the clock cycles between zerocrossings and sends count signals to the AND gate 236. The flip-flopwill then send zero crossing signals to the computer 222. Based uponthis count, the computer 222 will then compute the mass of the mailpiece 112 through an algorithm that allows computation by application ofthe above formulas. This computed mass is then shown on the display 226or sent to a postage setting device of a postage meter such as a Model6500 postage meter available from Pitney Bowes Inc.

Upon completion of weighing, the computer will disable the motor 48thereby providing no power to the belt 90. With this occurring, withreference to FIGS. 4, 5 and 7, the spring 160, which is overcome duringthe half revolution drive of the motor 84 will act upon the cam 154 torotate the shaft in a counter clockwise direction as shown in FIG. 7.With the rotation of the shaft in a counter clockwise direction, thecams 138,140 will rotate it so as to act upon one pair of arms 114 andthe rod 144 will push against the arms 114,115 to rotate them about theshafts 116 thereby lifting the brackets 128 and causing the belt 148 tobe inserted once more into the opening 44 of the tray 40.

With this same rotation of the shaft 70 caused by the spring 160, thecam 170 will rotate and thereby cause the link 180 to be rotated in aclockwise direction as seen in FIG. 9. As this occurs, the rectilinearabutment member 196 of the finger 194 slides upon the incline portion ofthe projection 188 thereby urging the tray 140 to the right as shown inFIG. 9. This continues until the rectangular abutment portion 196 fallsinto the shoulder 190 and is secured thereby. In this position, the tray40 is slightly to the right relative to its neutral position so that theflex members 30 are under tension. In this way, when the link 180 islifted, oscillation will occur as described previously.

Another activity that is taking place at this time results from theaction of the cam 220 upon the link 204. As the shaft 70 is rotated inthe counter clockwise direction, the cam is rotated so that it losesengagement with the link 204. With this occurring, the tension spring222 causes the link 204 to pivot about the pin 202 in a counterclockwise direction and the first leg 206 will press the leaf springs212,218 between it and the vertically extending portion of the stanchion200. With this occurring, the base 50 becomes locked once more to theframe.

All of the movements described heretofore are in response to thepresence of the one way bearing 74 that allows the shaft to beuneffected by drive of the pulley 72 when the motor is rotated in afirst direction, but allows drive of the shaft 70 when the pulley isdriven in the opposite direction so that the cams 138,140,170 and 220are driven thereby. In addition, one way bearing 80 allows the pulley 78to be rotated by the pulley 72 when the latter is driven in the firstdirection, but provides for free wheeling of the pulley 78 when thepulley 72 is driven in the second rotational direction. The finalelement in the design is the presence of the spring 160 that will returnthe shaft, and all its components, to the original position after themotor is disabled.

The flow chart of FIG. 14 describes the overall operation of theweighing scale 12. Mail pieces are conveyed 250 across the tray 40 andthe electronic system is initialized 252. The display is set up 254 andan inquiry made whether the first mail piece has passed 260. If thefirst mail piece has passed, the system waits for the envelope to reacha proper position 252. Upon the envelope reaching its proper position, areverse command signal is sent to the motor controller 264. The systemwaits for the motor to drive half a revolution and the motor is shutdown 268. At this point the start time is stored 270, which is followedby delay 272. The counters are clear 274 and, again, followed by a delay276. The zero crossings are cleared 278 and an inquiry made if thecrossings are ready 280. If yes, the crossing ready bit is cleared 282,and the zero crossing is enabled 284. An inquiry is made as to whetherthis is the last zero crossing 286, if not, the sequence of crossingready is repeated, but if so, the weight of the envelope is determined.After the weight of the envelope is determined, the motor is start torun the envelopes once more, and the results displayed 298. The mailpiece sensor is reset 300, an inquiry is made is whether this is thelast mail piece. If it is not the last mail piece, then the process ofweighing is repeated once more.

Using the method described above, one is able to obtain quite accuratedeterminations of the mass of articles placed upon the tray 40. Theaccuracy is better than 1/32 of an ounce for mail pieces up to 32ounces. Not only does one obtain an extremely accurate measurement ofthe mass, but it can be done in a rapid fashion. It has been found thata single mail piece 112 in a stream of mail pieces can be transportedonto the tray 40, stopped, weighed and ejected in about 325milliseconds. Overlapping entry of the next mail piece 112simultaneously with ejection of the preceding one provides for weighingat the rate of 184 mail pieces per minute. This represents a significantadvance in the weighing of articles in terms of cost, performance andsimplicity of electronics over prior weighing devices.

What is claimed is:
 1. A scale comprising:a frame a base, a plurality ofsprings connecting said base to said frame, a shaft rotatably supportedby said frame, an article supporting tray, an article conveyor supportedby said tray, at least one flexible member connecting said tray to saidbase, a transducer attached to said flexible member, a reversible motor,a first pulley coaxially disposed upon said shaft, a belt providingdrive between said motor and said pulley, a one way bearing mountedbetween said first pulley and said shaft whereby when said motor drivessaid first pulley in a first direction said shaft is driven thereby, acam mounted on said shaft, a link supported by said base and having acam follower in engagement with said cam, a finger depending from saidtray and engageable with said link, whereby upon rotation of said shaftin said first direction said link interacts with said finger to causeoscillation of said tray, a second pulley disposed about said firstpulley and connected to said article conveyor, and a second one waybearing mounted between said first pulley and said second pulley wherebyupon rotation of said first pulley by said motor in a second direction,said second pulley will be driven by said first pulley, to drive saidarticle conveyor whereby articles can be conveyed across said tray uponrotation of said first pulley in said second direction.
 2. The weighingscale of claim 1 wherein said link is generally L shaped with a firstarm having a cam follower and a second arm in engagement with saidfinger.
 3. The weighing scale of claim 2 wherein cam has a openingtherein with contoured surfaces and said cam follower is received withinsaid opening.
 4. The weighing scale of claim 3 including a springsupported by said frame and in engagement with said shaft to urge saidshaft in a rotational direction opposite to the driving rotation of saidfirst pulley.
 5. The weighing scale of claim 1 wherein said link isgenerally L shaped with a first arm having a cam follower and a secondarm in engagement with said finger.
 6. The weighing scale of claim 5wherein cam has a opening therein with contoured surfaces and said camfollower is received within said opening.
 7. A vibrating tray weighingscale having a frame, a base attached to a frame by isolation springs, atray connected to the base by flexure members, a transducer operativelyconnected to a flexure member to generate a voltage responsive to thedegree of flexuring of the flexure member, conveying mechanism fortransporting an object to be weighed onto and off of the tray, amechanism for vibrating the tray, and a computing device for determiningthe weight of the article of the tray in response to the voltagegenerated by the transducer, the improvement comprising: said vibratingmechanism including a finger depending from said tray and a linkrotatably mounted on said base and engageable with said finger.
 8. Theweighing scale of claim 7, wherein said finger has an abutment portionand said arm has a shoulder that are engageable whereby when said arm isin a first position said tray is locked in a position wherein saidflexure members have potential energy therein.
 9. The weighing scale ofclaim 8 wherein upon said arm being pivoted in a first direction saidfinger and said arm are disengaged from one another, said finger ismoved to a second position and said potential energy in said flexiblemembers is converted to kinetic energy.
 10. The weighing scale of claim9 wherein said arm has an angular bearing surface adjacent said shoulderto contact said finger and urge said finger toward said shoulder to movesaid finger from said second position to said first position as said armis pivoted in a second pivotal direction.
 11. A vibrating tray weighingscale having a frame, a base attached to a frame by isolation springs, atray connected to the base by flexure members, a transducer operativelyconnected to a flexure member to generate a voltage responsive to thedegree of flexuring of the flexure member, conveying mechanism fortransporting an object to be weighed onto and off of the tray, amechanism for vibrating the tray, and a computing device for determiningthe weight of the article of the tray in response to the voltagegenerated by the transducer, the improvement comprising: a shaftrotatably supported by said frame, said conveying mechanism including areversible motor, a first pulley coaxially disposed upon said shaft,drive means connecting said motor to said first pulley, a one waybearing mounted between said first pulley and said shaft whereby whensaid motor drives said first pulley in a first direction said shaft isdriven thereby, a cam mounted on said shaft, a link supported by saidbase and having a cam follower in engagement with said cam, a fingerdepending from said tray and engageable with said link, whereby uponrotation of said shaft in said first direction said link interacts withsaid finger to cause oscillation of said tray, a second pulley disposedabout said shaft and connected to said article conveying mechanism,drive means connecting said second pulley to said reversible motor, anda second one way bearing mounted between said second pulley and saidshaft whereby upon rotation of said second pulley by said motor saidconveying mechanism is driven.